Saved in:
Bibliographic Details
Main Authors: Tadmor-Shalev, Niva, Shemesh, Eli, Israel, Álvaro, Ghermandi, Andrea, Tchernov, Dan, Brook, Anna
Format: Artículo científico
Language:en
Published: Scientific reports 2026
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/41629414/
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1868266090067394561
author Tadmor-Shalev, Niva
Shemesh, Eli
Israel, Álvaro
Ghermandi, Andrea
Tchernov, Dan
Brook, Anna
author_facet Tadmor-Shalev, Niva
Shemesh, Eli
Israel, Álvaro
Ghermandi, Andrea
Tchernov, Dan
Brook, Anna
Tadmor-Shalev, Niva
Shemesh, Eli
Israel, Álvaro
Ghermandi, Andrea
Tchernov, Dan
Brook, Anna
collection PubMed - marine biology
contents Salinity stress enhances protein content and amino acid profile in Gracilaria cornea (Rhodophyta). Tadmor-Shalev, Niva Shemesh, Eli Israel, Álvaro Ghermandi, Andrea Tchernov, Dan Brook, Anna Amino Acids Gracilaria Salinity Salt Stress Plant Proteins Marine macroalga are frequently exposed to environmental stresses impairing their overall physiology and growth potential. Among these, Gracilaria cornea (Rhodophyta) is a valuable red seaweed rich in protein and polysaccharides. To investigate its physiological responses under controlled conditions, we cultivated Gracilaria cornea in an indoor culture system at three different salinity levels (30, 40 and 50 ppt), employing continuous aeration, blue and white LED illumination (12:12 light: dark cycle), and exogenous addition of nitrogen and phosphorus. Physiological changes associated with protein content accumulation and amino acid composition were determined using in-situ reflectance spectroscopy (VIS-NIR range 560-674 nm), AI algorithm and GC-MS analysis. We developed novel tools to accurately predict amino acid composition and total protein yield, identified the environmental factors inducing trait accumulation and determined the optimal harvesting day. Hypersaline stress and cultivation day significantly influenced protein content with optimal protein content (> 35% dry weight) achieved on day 14. This peak was not correlated with the specific growth rate (SGR), indicating SGR may not reliably indicate protein yield in this context. The dry weight to fresh weight ratio (DW: FW) was higher under hypersaline conditions, leading to a greater dried biomass and higher protein content, despite a reduced overall growth rate. Protein content was maximal under high ambient pH and high salinity. Day 14 was optimal for the highest yield of essential amino acids (EAA), exceeding 40% of the total amino acids. The algorithmic model accurately predicted specific amino acid proportions.
format Artículo científico
id pubmed_41629414
institution PubMed
language en
publishDate 2026
publisher Scientific reports
record_format pubmed
spellingShingle Salinity stress enhances protein content and amino acid profile in Gracilaria cornea (Rhodophyta).
Tadmor-Shalev, Niva
Shemesh, Eli
Israel, Álvaro
Ghermandi, Andrea
Tchernov, Dan
Brook, Anna
Amino Acids
Gracilaria
Salinity
Salt Stress
Plant Proteins
Salinity stress enhances protein content and amino acid profile in Gracilaria cornea (Rhodophyta). Tadmor-Shalev, Niva Shemesh, Eli Israel, Álvaro Ghermandi, Andrea Tchernov, Dan Brook, Anna Amino Acids Gracilaria Salinity Salt Stress Plant Proteins Marine macroalga are frequently exposed to environmental stresses impairing their overall physiology and growth potential. Among these, Gracilaria cornea (Rhodophyta) is a valuable red seaweed rich in protein and polysaccharides. To investigate its physiological responses under controlled conditions, we cultivated Gracilaria cornea in an indoor culture system at three different salinity levels (30, 40 and 50 ppt), employing continuous aeration, blue and white LED illumination (12:12 light: dark cycle), and exogenous addition of nitrogen and phosphorus. Physiological changes associated with protein content accumulation and amino acid composition were determined using in-situ reflectance spectroscopy (VIS-NIR range 560-674 nm), AI algorithm and GC-MS analysis. We developed novel tools to accurately predict amino acid composition and total protein yield, identified the environmental factors inducing trait accumulation and determined the optimal harvesting day. Hypersaline stress and cultivation day significantly influenced protein content with optimal protein content (> 35% dry weight) achieved on day 14. This peak was not correlated with the specific growth rate (SGR), indicating SGR may not reliably indicate protein yield in this context. The dry weight to fresh weight ratio (DW: FW) was higher under hypersaline conditions, leading to a greater dried biomass and higher protein content, despite a reduced overall growth rate. Protein content was maximal under high ambient pH and high salinity. Day 14 was optimal for the highest yield of essential amino acids (EAA), exceeding 40% of the total amino acids. The algorithmic model accurately predicted specific amino acid proportions.
title Salinity stress enhances protein content and amino acid profile in Gracilaria cornea (Rhodophyta).
topic Amino Acids
Gracilaria
Salinity
Salt Stress
Plant Proteins
url https://pubmed.ncbi.nlm.nih.gov/41629414/